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Acknowledgments. This work was supported by grants from the National Science Foundation, the National Institutes of Health (AI-07766), and the Petroleum Research Fund, administered by the American Chemical Society. We would like to thank Dr. R. L. Hansen of the Minnesota Mining and Manufacturing Co. for generous gifts of trifluoromethanesulfonic acid and anhydride. (14) National Institutes of Health Predoctoral Fellow, 1967-1970. (15) National Science Foundation Fellow, 1965-1967; American Machine and Foundry Fellow, 1967-1969.
R. C. Bi~igharn,’~ W. F. Sliwinski,a P. v. R. Schleyer Department of Chemistry, Princeton University Princeton, New Jersey 08540 Receiued March 10, 1970
Metalloboranes. V.’ Carbonyl Insertion in the Formation of Icosahedral Metalloboranes Sir: We wish to report a new direct synthesis of quasiicosahedral metalloboranes from the B10H13- ion and metal hexacarbonyls.2 This synthesis uniquely involves incorporation of a carbon atom in the icosahedral framework by a carbonyl insertion into the BloHla- ion. The resulting metalloboranes comprise two classes of complexes formally derived from the B1oHl~COH 3ligand3 (BioHioCOH)M(CO)r-
B i o H i O C O ~ ~ O ( C 02- ) )
1
2
with M = chromium, molybdenum, and tungsten. The class 2 ions have an unusual ether linkage between a carbonyl ligand and the icosahedral framework. Unlike other carboranes and metalloboranes, all representatives of these two classes are partially degraded by base with removal of a carbon atom, not a boron atom, from the icosahedral framework to give a )3~).~ new set of nido metalloboranes, B I ~ H I ~ M ( C O ( Irradiation (350 nm) of tetrahydrofuran solutions of NaBIOH18and the metal hexacarbonyls (inert atmosphere) gave the (Bl0HloCOH)M(C0)~-class 1 anions5 in 50 yield and treatment of these with sodium hydride gave quantitative yields of the yellow BloHloCOMCOL-J (C0)3*- class 2 ions.6
Figure 1. The bottom figure shows a side view of the BloHloCOMOCO(CO)~class 2 dianion with the terminal hydrogen atoms L-J
omitted. The top figure shows the corresponding top view of the dianion.
(BloHloCOH)M(C0)4-
THF + H- +
Ht
+ BioHioCOKCO(C0)a’-
(1)
The structure of the class 2 boranes was established by a single-crystal X-ray analysis of the tetrabutylammonium salt of BloHloCOMoCO(C0)32-class 2 ions L i
from 4000 pieces of data collected on a four-circle automatic diffractometer using Mo K a radiation. (1) Part I V : A. R. Kane, L. J. Guggenberger, and E. L. Muetterties, Crystals are triclinic, space group Pi2 with a = 13.492 J . Amer. Chem. Soc., 92,2571 (1970). (2) Metalloboranes which are 11 -atom icosahedral fragments have (6), b = 17.992 (lo), c = 11.271 (8) A, a = 104.02 (9), been prepared from BlOH13-: (a) N . N . Greenwood and N . F. Travers, p = 93.63 (16), and y = 105.78 (7)”. The observed J . Chem. Soc., A , 880 (1967); Chem. Commun., 216 (1967); (b) F. and calculated densities for two formula units per cell Klanberg, P. A. Wegner, G. W. Parshall, and E. L. Muetterties, Inorg. Chem., 7, 2073 (1968). are 1.12 and 1.10 g/cm3, respectively. No absorption (3) W. H . Knoth, J . Amer. Chem. Soc., 89, 3342 (1967). The correction was applied since the maximum p R was less BioH10COH3- ligand was not prepared in an uncomplexed form but was obtained in the (BloHloCOH)2Ni*-ion by reaction of nitrous acid than 0.1. The structure was solved by a combination and (BIoHIoCNH&N~. of Patterson and Fourier techniques. The results are (4) E. L. Muetterties and W. H . Knoth, “Polyhedral Boranes,” described for the least-squares refinement (R = 0.09) Marcel Dekker, New York,N. Y., 1968. ( 5 ) Sample characterization of [(CH~)~N](B~OHIOCOH)MO(CO)~. using the 2500 strongest reflections and a model with Anal. Calcd: C, 25.2; H, 5.62; B, 25.2; N, 3.26; 0 , 18.6; Mo, anisotropic thermal parameters for molybdenum and 22.3; formula wt, 430.2. Found: C, 25.6; H, 5.55; B, 25.2; N, five carbonyl groups and isotropic thermal parameters 3.29; 0, 18.0; Mo, 22.4; mol wt (osmometry-CHsCN), 211; equiv wt (titration of acid form), 395. 1lB nmr (32 MHz) (CHaCN) [Bfor the remaining nonhydrogen atoms. (0CHs)a = O] 16.4 (J = 108), 23.71 (J = 124), 27.67 (J = 128 Hz), The X-ray structure (Figure 1) shows that the class 2 31.38 (sh), 33.35 ppm (sh). Ir (THF) 3355 (m) (OH), 2510 (s) (B-H), 2063 (s), 1978 (s), 1950 cm-l(s) ( C r O ) ; (Nujol) 3480 cm-1 (s) (OH). ions have a metal atom completing a Bloc icosahedral
(6) Sample characterization of [(C~H~)IN]~[BIOHIOCOMOCO(CO)~]. L A CH& = 01 24.70 (J = 123), 28.95 (J = 148 Hz), 31.28, 36.40 ppm. Ir Anal. Calcd: C, 53.0; H, 9.79; B, 12.9; 0, 9.54; Mo, 11.4; (CH3CN) 2490 (s) (B-H); 1992 (s), 1908 (s), 1883 (s) (=O); 1659 formula wt, 838. Found: C, 52.6; H, 9.81; B, 14.4; 0, 10.7; Mo, (>C=O);(Nujol) 2495 (B-H), 1980 (s), 1905 (s), 1875 (s) ( C S O ) ; 11.9; mol wt (CHsCN), 443. 1lB nmr (32 MHz) (CH3CN) [B(O1662 cm-1 (>C=O).
Communications to the Editor
3474
framework. The unusual structural facet is a metal nucleus which is bonded to the carbon atom of a -COzgroup which in turn is linked through oxygen to the carbon atom in the polyhedral cage. Average bond distances are 1;97 (2) 8, for Mo-C(Cq), 1.16 (2) 8, for C-0, 1.70 (1) A for B-C, and 1.8 1 (1) A for B-B, where the errors are based on the differences observed for chemically sjmilar distances. Th? Mo-cage distances are 2.30 (1) A for Mo-C, 2.38 (1) A for Mo-B2(B5), and 2.44 (1) 8, for Mo-B3(B4); shorter distances are to be expected to the more electronegative carbon atom. The Mo-Con-cage bonding forces the eclipsing of two carbonyls with respect to the boron atoms, but the resultant intramolecular B-C(C0) contacts of 2.89 (6) 8, are not severe. The two unique (C4H&N+ ions are not disordered, but they d o exhibit a considerable amount of anisotropic thermal motion. The -CO%- linkage from C(l) to molybdenum is unique and the distances are similar to those observed in organic esters. The ester linkage is likely generated by intramolecular attack of an alkoxide ion formed during the reaction of class 1 ions with sodium hydride upon a coordinated carbonyl ligand. Intermolecular attack of alkyllithiums on carbonyl ligands to form coordinated “carbene” complexes is well known.’ The solution infrared spectra of the class 2 ions are in agreement with the X-ray structure. The terminal carbonyl bands are at lower frequencies than for the class 1 ions, consistent with the increased charge of the species, and there is a band in the ketonic carbonyl region (1660 cm- for the molybdenum complex). No hydroxyl group absorption was observed. The class 2 ions are quantitatively converted to 1 by aqueous acid in the absence of air. This reaction involves cleavage of the ether linkage to give a simple tetracarbonyl derivative of the BloCM icosahedron in which there is no bonding between the carbonyl groups and the cage. All spectral data are consistent with this structural formulation. The band in the infrared spectra of the three class 1 anions attributed to OH8 is observed in all salts and, in Nujol mulls or KBr pellets, it is sharp. In solution, the band shifts to lower frequencies arid broadens. Deuteration occurs only at the OH function, and for the molybdenum complex the ratio of the OH to O D stretching frequencies is 1.2. The broad pmr resonance of the OH group appears at about 7 8 for all class 1 ions, and this resonance sharpens and shifts to lower field on addition of DzO. The chemistry of the class 1 anions differs only in degree. The terminal carbonyl groups are relatively inert and resistant to displacement by phosphines or pyridine either under thermal or photochemical conditions. The ions are air sensitive, especially in aqueous solution, and degrade to borate. In the absence of oxygen, the class 1 ions do not react with nonoxidizing acids. The nido metalloboranes of structural class 3 are formed by the action of aqueous base on either class 1 or 2 ionsS9 Addition of acid does not lead to the regeneration of class 1 or 2 ions. The BloH12M(C0)42ions are very air sensitive, especially in acid solutions,
but there is no hydrolysis in the absence of oxygen. The infrared spectrum has BH and terminal carbonyl absorptions but none attributable to hydroxyl or ketonic functions. Structurally, we believe that the class 3 ions are strictly analogous to the 11-atom icosahedral fragment metalloboranes earlier described for the B,,H12*- complexes of metal ions derived from the group VI11 and post-transition metals.2b P. A. Wegner, L. J. Guggenberger, E. L. Muetterties Contributioti No. 1685, Central Research Department E. I . du Pont de Nemours and Company Experimental Station, Wilmirigton, Delaware 19898 Receiced April IO, 1970
Walk Processes in Photochemical Molecular Rearrangements. A General Photochemical Transformation. Mechanistic and Exploratory Organic Photochemistry. LVIIl Sir : In our description2 of the photochemical rearrangements of l-methylene-4,4-diphenyl-2,5-cyclohexadiene (1) to trans-5,6-dipheny1-2-methylenebicyclo[3.1 .O]-3hexene (3) a secondary photoproduct (4), shown to derive from further photolysis of product 3, was mentioned. We now report (1) the structure of photoproduct 4, (2) that this product arises from a novel and general process in which a carbenoid carbon walks from one end of a butadiene moiety to the other, (3) the quantum efficiencies which are relatively independent of structure, (4) that the process proceeds only by way of the singlet-excited state, (5) the freedom of motion of the carbenoid group on the face of the ?r system, (6)stereochemical evidence suggesting a slither mechanism, and (7) the extreme reluctance of the methylene dienone analog 2 t o rearrange in contrast to acyclic di-rmethanes and cyclohexadienones. Thus, the product of direct photolysis of truns-5,6dipheny1-2-methylenebicyclo[3.1.0]-3-hexene (3) was shown (ride infra) to be 1,5-diphenylspiro[2.4]-4,6-heptadiene (4). Similarly, 6,6-dimethyl-2-methylenebi-
1, R=Ph 2, R = CHJ
3, R,, R,= Ph; R,=H 5 , R,= H; R,, R, = CH,
4a, R,, R, = Ph; R2 = H 4b, R,, RL= Ph; R, = H 6, R, = H; R2,RJ = CH,
(1) For paper LVI note H. E. Zimmerman and A. C. Pratt, J . Amer. (7) E. 0.Fischer and A. Maasbol, Chem. Ber., 100,2445 (1967). (8) A similar band was observed in spectra of the (B1OH1OCOH)2Ni2Chem. Soc., in press. (2) H . E. Zimmerman, P. Hackett, D. Juers, and B. Schroder, ibid., ion. (9) Sample characterization of [(C~H~)~N]ZBIOHI?MO(CO)~. Anal. 89, 5973 (1967). (3) H. E. Zimmerman, D. S. Crumrine, D. Dopp, and P. S. Huyffer, Calcd: C, 48.2; H, 9.30; N, 4.02; B, 15.5; Mo, 13.7. Found: C, 47.9; H,9.17; N, 4.13; B, 15.3; Mo, 13.3. ibid., 91,434 (1969).
Journal of the American Chemical Society
1 92:11
June 3, 1970